plants
Conference Report
Proceedings of the 7th Series of Seminars on Advances in
Apomixis Research
Viviana Echenique 1,2,*, Daphné Autran 3 and Olivier Leblanc 3,*
1 Centro de Recursos Naturales Renovables de la Zona Semiárida (CERZOS-CCT Bahía Blanca—CONICET),
Bahía Blanca 8000, Argentina
2 Departamento de Agronomía, Universidad Nacional del Sur (UNS), Bahía Blanca 8000, Argentina
3 DIADE, Université de Montpellier, CIRAD, IRD, Montpellier, France; daphne.autran@ird.fr
* Correspondence: echeniq@cerzos-conicet.gob.ar (V.E.); olivier.leblanc@ird.fr (O.L.)
Abstract: These proceedings contain the abstracts for the presentations given at the 7th biennial
Seminars on Advances in Apomixis Research, held virtually on 2–3 and 9 December 2020. The first
day hosted the kick-off meeting of the EU-funded Mechanisms of Apomictic Development (MAD)
project, while the remaining days were dedicated to oral presentations and in-depth exchanges on
the latest progress in the field of apomixis and plant reproductive biology research.
Keywords: apomixis; seed development; flowering plants; regulation of gene expression; H2020-
MSCA-RISE-2020
1. Introduction





 A staggering increase in food production will be needed to feed a population of nearly
Citation: Echenique, V.; Autran, D.; 10 billion people in the near future. The growing consensus is that global food demand
Leblanc, O. Proceedings of the 7th will double during the next 50 years, representing twice as much as the total amount
Series of Seminars on Advances in produced since the beginning of agriculture 10,000 years ago [1]. The need for robust,
Apomixis Research. Plants 2021, 10, high-yielding crops adapted to diverse and changing environments is a cornerstone of
565. https://doi.org/10.3390/ sustainable development that strongly rely on new agriculture practices and molecular
plants10030565 technologies [2,3]. To achieve this, plant reproductive biology represents a challenging
research area. Understanding the intricate networks controlling germline development,
Academic Editor: Fulvio Pupilli double fertilization, and seed formation is crucial for delivering innovative approaches
to breeders and farmers [4,5]. In this context, the harnessing of apomixis, a natural phe-
Received: 13 February 2021 nomenon allowing the formation of maternal embryos within seeds [6,7], is among the most
Accepted: 15 March 2021 promising approaches [8]. Breeding processes typically consist of large-scale designs aimed
Published: 17 March 2021 at exploring the phenotypic value of thousands of genetically fixed (i.e., reproducible)
allelic assortments. However, the biology of crop species, including sexual reproduction,
Publisher’s Note: MDPI stays neutral renders the implementation of these operations complex, time-consuming, and usually
with regard to jurisdictional claims in expensive (e.g., [9]). In contrast, any apomictic genotype breeds true, including that of
published maps and institutional affil- F1 hybrids perpetuating hybrid vigor (or heterosis) over generations [10]. The fixation
iations.
of heterosis through apomixis would greatly facilitate the deployment of hybrid seed
technologies in autogamous crops such as wheat or rice and reduce costs of hybrid seed
production in allogamous crops such as maize [11–13]. In addition, installing apomixis
in major crops could also accelerate breeding cycles and increase variety turn-over, ex-
Copyright: © 2021 by the authors. pand genetic diversity by overcoming meiotic sterility resulting from wide crosses and
Licensee MDPI, Basel, Switzerland. inter- or high ploidy crosses. Apomixis encompasses numerous developmental paths
This article is an open access article that fall into adventitious embryony where sexually derived seeds harbor a typical sexual
distributed under the terms and embryo together with maternal embryos directly formed from maternal tissues and game-
conditions of the Creative Commons
tophytic apomixis, where seeds derive from non-reduced female gametophytes carrying
Attribution (CC BY) license (https://
parthenogenetic embryos (Figure 1) [6,14]. Apomixis is usually inherited in a dominant
creativecommons.org/licenses/by/
manner through a limited number of loci, but the suppression of recombination in the
4.0/).
Plants 2021, 10, 565. https://doi.org/10.3390/plants10030565 https://www.mdpi.com/journal/plants
Plants 2021, 10, x FOR PEER REVIEW 2 of 18 
 
Plants 2021, 10, 565 2 of 17
dominant manner through a limited number of loci, but the suppression of recombination 
in the region bearing these loci suggests a more complex genetic control [6,7,14–16]. Nev-
ertrhegeiloenssb, enaurimngetrhoeuses lwocoirskusg ginesdtsicaamteo trheec oinmtpimlexacgye noeft itchceosnet rpoal t[6h,w7,1a4y–s1 6w].itNhe tvheert hfaecletsosr,s con-
tronlulimnge rfoeums awleo rgkesrimndliincaet esptheeciifnictiamtiaocny aonf dth deseevpelaothpwmaeynst,w ainthdt heemfbarcytor sfocromntarotilolin gwithin 
ovfuemlesa loefg seerxmulainl epslapnectsifi [c1a7t,i1o8n].a Undnfdoervteulnopatmeleyn,t ,daensdpietme dbreycoadfoersm oaft rioensewaritchi,n noevituhlesr otrfansfer 
attseemxupatlsp flaronmts  [w17i,l1d8 ].apUonmforictutinca rtellya,tdiveseps itientdoe cmadaeiszeo f[r1e9s]e aorrc hp,enaeritlh meriltlreatn s[f2e0r]a nttoemr tphtse engi-
neferroimngw oifld apapoommicicttiicc rreeplartoivdeuscitniotonm ina iaz ese[1x9u]aolr cproeapr l[1m3i]l lheat v[2e0 ]ynieolrdtehde tehneg ienxepeericntegdo fresults 
anadp tohmei cetsitcarbelpisrhodmuecntito onfi fnuancsteixounaallc aroppom[1i3x]ihs aivne myaiejoldre cdrothpes erxepmeactiends reeasgueltrslya nadwtahieted. 
establishment of functional apomixis in major crops remains eagerly awaited.
A B 
C reduced reduced sexual  megaspore gametophyte seed 
sexuality meiosis 
egg fertilization 
MMC 
sperm 
diplospory apomeiosis 
AI parthenogenesis egg 
ovule apospory 
unreduced unreduced clonal  
megaspore gametophyte seed 
Figure 1. Argentinean apomictic grasses and apomixis reproductive pathways. (A)  Pastures of
FigPuasrpea l1u.m Anrogteatnutmin, eaanne xaapmopmleicotfica pgorsapsosreosu asnpdla anpt.o(Bm)iExriasg rreosptrisocduurvcutilav,ea npaexthamwpalyeso. f(Adi)p Ploassptourroeuss of 
Papsplaanlut.m(C n)oStacthuemm,a atinc erexparmespenlet aotfio anpsoosfpsoerxouuals apnldanatp. o(mB)i cEtircagrerposrotids uccutrivvue lpaa, tahnw eaxyasm. Ipnlsee oxuf adliiptylo-
spo(troopu),sa pslianngtle. (cCel)l Socf htheemoavtuicle reenptreerssethnetagteiormnsli noef sdeifxfeuraeln atinatdio anppormogircatimc ,rtehpersood-cuacllteivdem peagtahswpoaryes. In 
sexmuoatlhiteyr (cteollp()M, aM sCin)g. Tleh ceeMll MofC thuen doevrugloee esnmteerios stihs,eh geenrcme floinrme dinigffearreendtuiacteidon(h parpologirda)mfu, nthcteio snoa-lcalled 
mesgpaosrpe o(mree mgaospthoerre )c,etlhla (tMdMiffeCr)e.n Ttihaete Ms iMntoC aurneddeurcgeodegs ammeeitoospihs,y hteenhacreb foorrimnginthge af ermedaulecegdam (heateploid) 
fun(ecgtgio).nAalf tseproferret i(lmizaetgioanspoof rthe)e, etghgatb dyiaffsepreernmtiacteells, ainsteox uaa rlesdeuedceisdf gorammeedt.oIpnhayptoem hiacrtibcoprainthgw tahyes ,female 
gamfunetceti o(engagl u).n Arefdteurc efedrfteilmizaalteiognam oef ttohpeh yegtegs barye afo srpmeerdm( acpeollm, ae isoesxisu),aaln sdeeudn riesd fuocremdeedg.g Isnd aepveolmopictic 
paitnhtwo amyast,e rfnuanlcetmiobnraylo us ninrethdeuacbesde nfecemoaflfee rgtailmizaettioonph(pyatretsh eanroeg feonremsies)d,  r(easpuoltminegiionsisse)e,d asncdo nutanirneidnguced 
eggclso ndeesveolfotph einmtoo tmhearteprlnaanlt .emInbdryipolso sipno trhye( ambisdednlec)e, omf efieorstiislizinattihoen M(pMarCthfeanilso.geTnheesuisn),r erdesuuceltding in 
seefedms acloengtaamineitnogp hcylotentehse onfa trhisee smforotmhear npulannret.d Iunc eddipmloegspasoproyr e(m. Inidadploes)p, moryei(obsoitst oinm t)h, oen Me oMr Cm ofareils. The 
unsroemduatciecdo vfeumleacleel lgsadmifefetorepnhtiyattee tihneton aaproissepso frrooums  iannit iualnsr(eAdIus)c,etdh empergeacusprsoorre.c eInlls aopfouspnroerdyu (cbeodttom), 
onfee mora lme ogarem seotompahtyitce so.vule cells differentiate into aposporous initials (AIs), the precursor cells of 
unreduTceodg faeimn aalde egeapmeretuonpdheyrtsetsa. nding of the genetic and molecular bases of gametophytic
apomixis from natural systems, an international research network was initiated by Ar-
genTtoin giaaninsc aie dnetiesptseirn u2n0d08erasttathnedCinegn torof tdheeR geecnuerstiocs aNnadt umraolleescRuelanro vbaabsleess odfe glaamZoentoaphytic 
apSoemiixáirsid faro(CmE nRaZtOuSraCl OsyNstICemETs—, aUnn iinvteerrsnidaatidoNnaalc iroensaeladrcehl S nuert,wBaohrika wBlaasn cina,itAiargteedn tbinya A). rgen-
tinian scientists in 2008 at the Centro de Recursos Naturales Renovables de la Zona 
Semiárida (CERZOS CONICET—Universidad Nacional del Sur, Bahia Blanca, Argentina). 
Since then, a series of biennial Seminars on Advances in Apomixis Research, has been held 
 
Plants 2021, 10, 565 3 of 17
Since then, a series of biennial Seminars on Advances in Apomixis Research, has been
held in Argentina, under rotating chairing by scientists from CERZOS, the Instituto de
Investigaciones en Ciencias Agrarias de Rosario (IICAR CONICET—Universidad de Na-
cional de Rosario, Santa Fe, Argentina) and the Instituto de Botánica del Nordeste (IBONE
CONICET—Universidad Nacional del Nordeste, Corrientes, Corrientes, Argentina). This
network has gathered momentum, size, and strength owing to support from the Euro-
pean Union’s Horizon H2020 research and innovation programme through two Marie
Skłodowska-Curie grant agreements: Harnessing Plant Reproduction for Crop Improve-
ment (PROCROP, 2014–2018, n◦ 645674) and Mechanisms of Apomictic Development
(MAD, 2020–2024, n◦ 872417) which kick-off meeting was organized as a one-day session of
the 7th Series of Seminars on Advances in Apomixis Research. These proceedings contain
a brief report of the MAD kick-off meeting and the abstracts of the presentations given at
the 7th Seminars on Advances in Apomixis Research, chaired by Prof. Viviana Echenique
from CERZOS-CCT.
2. Launch of the Mechanisms of Apomictic Development (MAD) Project
Leblanc O
DIADE, Univ Montpellier, CIRAD, IRD, Montpellier France
The Mechanisms of Apomictic Development (MAD) project that brings together young
and experienced scientists from 12 laboratories from Europe, the Americas, and Australia
(Table S1), was launched 1 December 2020. This 48-month project consists of a Marie
Skłodowska-Curie Research and Innovation Staff Exchange (MSCA RISE) Action funded
by the European Union’s H2020 Programme and aimed at supporting international and in-
tersectoral collaboration through the exchange of research and innovation staff. The kick-off
meeting was held on 2 December 2020, in conjunction with the 7th Seminars on Advances
in Apomixis Research, with a two-session agenda dedicated to partners/work packages
presentations and to management issues. Here, a report for the first session is provided,
including the summary of the project, an overview of the proposed work packages, and the
list of participating institutions and contacts. More information is available from the
EU CORDIS portal (https://cordis.europa.eu/project/id/872417 (accessed on 3 February
2021)), and a dedicated website will be set up online in the forthcoming weeks.
2.1. Project Summary
Apomixis in plants allows the formation of seeds carrying maternal embryos. While ab-
sent in major food crops, it occurs in many plants, including wild relatives of cereals and
species of economic interest such as forage grasses and fruit trees. This unique reproductive
mode can be achieved through many paths, all involving alterations in the orchestration of
the developmental programs underlying sexual reproduction (Figure 1). Since it allows
the use of a natural carrier, the seed, for propagating the best genotypes regardless of
their constitution, apomixis represents a revolutionary tool for plant breeding programs
and for reducing the costs of improved variety seeds. Despite wide-cross breeding pro-
grams to introduce the trait in cereals and decades of research using both sexual plant
models and apomictic species, apomixis remains an enigma for plant biologists and a
long-awaited tool by breeders and farmers. Functional analyses in Arabidopsis and maize
have provided valuable molecular information to understand sexual reproduction and,
occasionally, to explore alterations yielding phenotypes reminiscent of apomixis. On the
other hand, the recent advances in « omics » tools and biotechnologies have opened the
route for investigating apomictic species at unprecedented, cellular, and molecular levels.
The MAD (Mechanisms of Apomictic Development) project will establish an international,
research and training network aiming at contributing significantly to our understanding of
key mechanisms involved in redirecting sexuality in plants towards apomixis. It bridges
critical knowledge and biological resources recently generated by collaborative efforts in
the field of apomixis biology, and novel expertise in plant reproductive biology, biotechnol-
ogy, and breeding by aggregating new partners. Synergies are expected from three types of
Plants 2021, 10, 565 4 of 17
complementarities, including the following: biological systems and resources prone to fuel
comparative and translational research (Table 1); a wide range of approaches (e.g., genetics
and genomics, 3D quantitative imaging, growth modeling) to better integrate knowledge
on reproductive development and apomixis; and a spectrum of scientific questions cov-
ering all aspects. Through research, training, and dissemination actions, the project will
clarify the genetic architecture of apomixis and support the deployment of innovative
strategies in crop improvement.
Table 1. Sexual and apomictic systems studied in Mechanisms of Apomictic Development (MAD).
Species Status (See Figure 1C) Available Resources
Arabidopsis thaliana, Sexual model species Genetic stocks (mutants, reporter lines),Rice, maize transcriptomic resources
Boechera holboellii Apomictic relative of A. thaliana Germplasm collection, genomic, and(diplospory) transcriptomic resources, candidate genes
Hypericum perforatum Apomictic species (apospory) Transcriptomic resources, candidate genes
Germplasm collection, genomics, and
Paspalum ssp. (Figure 1A) Apomictic subtropical forage grasses transcriptomic resources, linkage maps,(apospory) candidate genes, detailed reproductive
calendars, genetic transformation
Eragrostis curvula (Figure 1B) Apomictic subtropical forage grass Genomics and transcriptomic resources,(diplospory) linkage maps, candidate genes
2.2. Work Packages Overview
The project proposes an interconnected portfolio of six work packages (WP) to ensure
transparent and effective governance, compliance with scientific and education objectives,
and wide visibility of objectives and achievements. WPs 1 and 2 are dedicated to Man-
agement & Coordination and to Communication & Dissemination, while each of the four
remaining WPs addresses a unique scientific question using comparative and translational
approaches. Any progress in a given WP is prone to fuel advances in the other ones.
In the first scientific WP (WP3), we will investigate the functional role of the het-
erochromatic genomic regions specific to apomicts genomes. To address this, we will
decipher the structural and functional features of the locus controlling apomictic repro-
duction (Apomixis Controlling Locus, ACL) in natural apomictic grasses belonging to the
Eragrostis and Paspalum genera (Figure 1A,B) and provide a general view of how apomic-
tic genomes work as a whole. The proposed tasks will intend to unveil the gene content
of the ACLs in several species under study and to compare its conservation, to identify
regions prone to contain genes controlling key components of apomictic reproduction,
and to propose hypotheses for the evolution of apomictic genomes.
The following WP (WP4) aims at characterizing genes regulatory mechanisms in-
volved in apomixis control. Are the transcriptional patterns promoting apomixis shaped
transcriptionally or post-transcriptionally? To address this question, WP4 is designed to
typify the function of selected candidate genes for apomixis control, that belong to either
transcriptional or post-transcriptional regulatory pathways, and to analyze the occurrence
of changes in the epigenome of the respective mutants/transformants.
Next, in WP5, we will address the regulatory role of phytohormones, in particular,
how do phytohormones interact to establish and control the reproductive cell fate during
plant reproduction. To address this, we will two main questions: (a) how do auxin and
cytokinin signaling coordinate MMC cell fate and female gametophyte development in
sexual vs. apomictic Paspalum notatum, and (b) which of the differentially expressed rele-
vant genes identified in the course of WP4 has a hormonal-related role in the specification
of sexual vs. apomictic germline precursors cell fate?
Finally, in WP6, we will ask whether ovule architecture also contributes to the control
of apomixis and, notably, to female germline fate. To answer this question, this work
Plants 2021, 10, 565 5 of 17
package will build on preliminary results in Arabidopsis suggesting that altering ovule
architecture changes the plasticity of reproductive cells fate in the ovule. By combining
imaging and functional approaches, this WP focuses on the cellular parameters of the early
ovule associated with, and predicting, the plasticity of the differentiation of the germline
precursor cells, in sexual and apomictic plants.
2.3. Partner Institutions and Contact Persons
The MAD project is coordinated by Dr. Olivier Leblanc (PI) and Maïa Lejbowicz
(project manager) from the Institut de Recherche pour le Développement (IRD), Plant Di-
versity Adaptation and Development Joint Research Unit (DIADE Univ Montpellier—
CIRAD—IRD), France. In addition to IRD, participating institutions and contact persons
include: University of Milan, Biosciences Department, Italy (Prof. Lucia Colombo); Uni-
versity of Perugia, Department of Agricultural, Food and Environmental Sciences, Italy
(Prof. Emidio Albertini); University of Padova, Department of Agronomy Food Natural
Resources Animals and Environment, Italy (Prof. Gianni Barcaccia); Institute of Bio-
sciences and BioResources, National Research Council, Italy (Dr. Fulvio Pupilli); National
Institute for Agricultural Biology (NIAB), Crop Bioinformatics group, UK (Dr. Mario
Caccamo); University of Zürich, Department of Plant and Microbial Biology, Switzerland
(Prof. Ueli Grossniklaus); CONICET—Universidad de Nacional de Rosario, Instituto de
Investigaciones en Ciencias Agrarias de Rosario (IICAR), Argentina. (Prof. Silvina Pessino);
CONICET—Universidad Nacional del Noreste, Instituto de Botánica del Nordeste (IBONE),
Argentina (Dr. Francisco Espinoza); CONICET—Universidad Nacional del Sur, Centro
de Recursos Naturales Renovables de la Zona Semiárida (CERZOS), Argentina (Prof. Vi-
viana Echenique); University of Adelaide, School of Agriculture, Food and Wine, Australia
(Prof. Matthew Tucker), and; CINVESTAV, Laboratorio Nacional de Genómica para la
Biodiversidad (LANGEBIO), Mexico (Prof. Stewart Gillmor).
3. Abstracts of Presentations of the 7th Series of Seminars on Advances in
Apomixis Research
Presentations focused on various issues pertaining to the biology of apomixis and
apomictic forage grass breeding and were assembled into three sessions. The first one,
Ovule development and reproductive fate, contains works investigating the control of
female germline fate and how regulatory mechanisms are coordinated in both the sexual
Arabidopsis model plant and apomictic grasses. The following section, Genomics and
epigenomics of apomixis, addresses comparative genomics and epigenomics using different
apomictic biological systems, to investigate the role of hybridity and polyploidy and
examine the origin and nature of allelic variation at candidate loci. The last session,
Agronomic traits and breeding approaches in apomictic forage grasses, focuses on aspects
of germplasm enhancement and breeding in subtropical grass forages.
3.1. Ovule Development and Reproductive Fate
3.1.1. Cloning of Diplosporous Apomixis Candidate Genes for Its Functional
Characterization in the Model Plant Arabidopsis thaliana
Pasten MC *, Bellido A *, Garbus I and Echenique V
Centro de Recursos Naturales Renovables de la Zona Semiárida (CERZOS- CONICET)
and Departamento de Agronomía, Universidad Nacional del Sur (UNS), Bahía Blanca, Ar-
gentina. * These authors contributed equally to this work: mcpasten@cerzos-conicet.gob.ar,
andresbellido@gmail.com.
Eragrostis curvula is a perennial forage grass naturalized in semiarid regions of Ar-
gentina, with genotypes that can be either sexual diploids or polyploids (4×–8×) reproduc-
ing by diplosporous apomixis. Using different approaches, our research group obtained
a list of candidate genes related to this reproductive mode that remain to be functionally
characterized. The aim of this work is to optimize the construction of vectors for the
introduction of these Eragrostis candidate genes into the model plant Arabidopsis thaliana
in order to analyze their effects during reproductive development. Two strategies were
Plants 2021, 10, 565 6 of 17
used, Gateway and GoldenBraid, and vectors with single and multiple genes were intro-
duced in A. thaliana plants using Agrobacterium and the floral dip method. In relation
to GoldenBraid, focusing on the current knowledge about the complex dynamics that
regulate germline specification in the ovule of A. thaliana, different promoters were se-
lected, related to these key pathways, which will guide ectopic expression into the regions
surrounding the MMC. Currently, using these promoters in the GoldenBraid system, con-
structs for each gene were generated, and vectors containing different combinations of
genes were successfully created, using kanamycin or hygromycin for the selection of the
transgenic plants. The phenotypic effects of these genes will be analyzed in the near future,
using whole mount clearing and DIC microscopy.
3.1.2. Early Ovule Morphogenesis and Germ Cells Formation
Autran D 1,*, Baroux C 2, Hernandez-Lagana E 1, Mosca G 2, Mendocilla Sato E 2,
Pires N 2, Frey A 2, Giraldo-Fonseca A 2, Grossniklaus U 2, Hamant O 3, Godin C 3,
Boudaoud A 3,4, Grimanelli G 1, Delgado L 5, Conejero G 6, Lartaud M 6
1 DIADE, University of Montpellier, CIRAD, IRD, Montpellier, France; 2 Department
of Plant and Microbial Biology and Zurich-Basel Plant Science Center, University of Zürich,
Zürich, Switzerland; 3 RDP, University of Lyon, ENS Lyon, UCB Lyon 1, CNRS, INRAE,
INRIA, Lyon, France; 4 Present address: LadHyX, Ecole polytechnique, CNRS, Institut Poly-
technique de Paris, Palaiseau, France; 5 Instituto de Investigaciones en Ciencias Agrarias
de Rosario (IICAR), CONICET, FCA UNR, Rosario, Argentina. 6 AGAP, University of
Montpellier, CIRAD, Montpellier, France. * daphne.autran@ird.fr
In flowering sexual plants, the female germline precursor differentiates as a single
spore mother cell, so-called Megaspore Mother Cell (MMC). MMC formation is con-
temporary to early ovule primordium growth. Here, we explored how organ growth
contributes to MMC differentiation. In the model plant Arabidopsis, by quantitative anal-
ysis of 3D images at cellular resolution, cell cycle markers, and tissue growth models,
we identified spatio-temporal patterns of cell growth and divisions in the early ovule
primordium. Our analysis revealed that MMC characteristics first arise in more than
one cell, but MMC fate becomes progressively restricted to a single cell during organ
growth. Altered primordium growth patterns in katanin mutants—affected in microtubules
dynamics—coincided with a delay in the MMC fate restriction process. We propose a model
of gradual canalization of reproductive cell fate coupled to ovule primordium growth in
Arabidopsis. Further studies should determine if this model is conserved in ovules of
grasses; either sexual such as in maize, or following an aposporous reproductive mode,
such as in Paspalum.
3.1.3. The RdDM Pathway Is Important to Specify a Single Female Germ Cell Precursor
through the Restriction of Sporocyteless/Nozzle Expression
Mendes MA 1,*, Petrella R 1, Cucinotta M 1, Vignati E 1, Gatti S 1, Pinto SC 2, Bird
DC 3, Gregis V 1, Dickinson H 4, Tucker MR 3, Colombo L 1
1 Dipartimento di Bioscienze, Università degli Studi di Milano, Via Celoria 26, 20133 Mi-
lano, Italy; 2 LAQV REQUIMTE, Departamento de Biologia, Faculdade de Ciências, Uni-
versidade do Porto, Rua do Campo Alegre s/n, 4169-007 Porto, Portugal; 3 School of
Agriculture, Food, and Wine, The University of Adelaide, Waite Campus, Urrbrae, SA5064,
Australia; 4 Department of Plant Sciences, University of Oxford, South Parks Road, Ox-
ford OX1 3RB, UK. * marta.miranda@unimi.it
The female gametophyte formation starts from the differentiation of a single cell in the
pre-meiotic ovule, named megaspore mother cell (MMC). Formerly, it was reported that
mutants in RNA-dependent DNA methylation—RdDM pathway showed more than one
MMC-like cell. We have recently shown that the DRM methyltransferase double mutant
drm1drm2 also presents supernumerary MMC-like cells, consistent with RdDM mutants’
phenotype. We have also demonstrated that SPOROCYTELESS/NOZZLE (SPL/NZZ) a
transcription factor required for MMC specification is ectopically expressed in ago9 and
drm1drm2 mutants suggesting that the multiple MMC-like phenotype might be due to
Plants 2021, 10, 565 7 of 17
its ectopic expression. Interestingly we show that the ovule identity gene SEEDSTICK,
directly regulates the two RdDM players AGO9 and RDR6 expression in the ovule and,
therefore, indirectly SPL/NZZ. Based on our and previous results, we have so proposed a
model describing the network required to restrict SPL/NZZ expression to specify a single
MMC. In the future, our focus will be to uncover in more detail the mechanisms controlling
MMC specification and, in particular, SPL/NZZ expression.
3.1.4. Depletion of Trimethylguanosine Synthase1 Alters Reproductive Development
in Arabidopsis
Siena LA 1,*, Michaud C 2, Selles B 2,3, Pessino SC 1, Ingouff M 2, Ortiz JPA 1,
Leblanc O 2
1 Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR), CONICET,
FCA UNR, Rosario, Argentina; 2 DIADE, Univ Montpellier, CIRAD, IRD, Montpellier,
France; 3 Current address: Université de Lorraine, INRAE, IAM, F-54000 Nancy, France.
* siena@iicar-conicet.gob.ar
In flowering plants, apomixis refers to asexual reproduction through seeds. Recently,
we identified a plant ortholog of yeast trimethylguanosine synthase1 (TGS1), whose expres-
sion is positively correlated with the rate of sexuality in reproductive tissues of facultative
apomictic Paspalum notatum genotypes. In yeast, mammals and insects, TGS1 is encoded by
a single gene and performs multiples activities. It catalyzes 5′ cap trimethylation of noncod-
ing RNAs, plays a role in the biogenesis of sn(o)RNAs, rRNA processing, and telomerase
function. Moreover, it acts as a transcriptional co-activator associated with PRIP. The struc-
ture and function of TGS1 orthologs in plants remain poorly characterized. Plants contain
a specific copy with a WW interaction domain at the N-terminal. To explore TGS1 possible
association with apomixis, we determined its expression patterns in Arabidopsis and
studied its loss of function in two T-DNA insertion lines. RT-PCR revealed preferential
expression of TGS1 in reproductive tissues. Transgenic plants carrying synthetic reporter
constructs (pTGS1:TGS1: GUS/GFP) showed it is expressed throughout female gametogen-
esis and embryogenesis, but not in the nucellus. Mutant plants showed reduced fertility,
and mutant allele transmission suggested gametophytic effects, with stronger bias when
maternally transmitted. Cytoembryological analyses showed apomixis-like phenotypes, in-
cluding multiple megaspore mother cells and embryo sacs, and extra embryos. Cell-identity
markers revealed cell-fate alterations during both female gametogenesis and early seed
development. Moreover, germination rate and seedling defects were observed. The knowl-
edge gained indicates an essential role for TGS1 during sexual female gametogenesis and
embryo patterning in plants.
3.1.5. Preliminary Studies of the Role of TGS1 in sRNA Methylation and Splicing during
Paspalum Notatum Reproductive Development
Colono CM *, Podio M, Pessino SC
Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR), CONICET,
FCA UNR, Rosario, Argentina. * colono@iicar-conicet.gob.ar
Paspalum notatum is one of the main apomixis grass models. Previous transcriptome
analysis further validated by mRNA in situ hybridization revealed that the gene TGS1
(encoding the RNA methyltransferase TRIMETILGUANOSINE SYNTHASE 1) is repressed
in ovules of apomictic P. notatum plants. In animals and/or yeasts, TGS1 promotes the
processing several RNA types and also acts as a transcriptional co-activator. Recently,
we reported that silencing of TGS1 causes the emergence of foliar trichomes and super-
numerary aposporous-like embryo sacs in P. notatum, which led to its classification as a
developmental repressor. Our objective here was to analyze whether TGS1 influences RNA
processing in this species. Three-hundred and sixteen (316) RNA transcripts differentially
expressed in flowers of apomictic and sexual plants were selected to examine the existence
of putative splice variants. Using qRT-PCR analysis, we confirmed that an unprocessed
splicing variant of one of them (CHLOROPHYLL A-B BINDING PROTEIN 1B-21, renamed
CHLORO) is less represented in apomictic plants at a statistically significant level. The same
Plants 2021, 10, 565 8 of 17
unprocessed splicing variant also diminished in antisense tgs1 sexual lines. Moreover,
since we identified seven miRNAs upregulated in floral sRNA libraries of sexual P. notatum
plants, we are testing their representations in the same tgs1 antisense lines. Our conclusion
is that TGS1 influences the splicing of CHLORO, a component of the photosynthesis light-
harvesting the photosynthesis antenna, which might relate with the role of this gene as leaf
trichomes formation repressor. The function of TGS1 in miRNA regulation remains unclear.
3.1.6. Identification of PPI_FKBP Transcripts Expressed during Paspalum notatum
Reproductive Development and Their Relationship with Apomixis
Stein J *, Spoto N, Podio M, Ortiz JPA
Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR-CONICET-UNR),
Zavalla, Argentina. * jstein@unr.edu.ar
In Paspalum notatum apomixis is governed by a single dominant 36 Mpb-long super-
locus (ACL), showing strong restriction of recombination and association with a highly
methylated heterochromatic knob. Genomic sequencing revealed the presence of repetitive
segments and single-copy genes, while synteny studies indicated its location into a ‘hybrid’
genomic region carrying markers from rice chromosomes 2 and 12. Particularly, the RFLP
marker C932 (rice Chr. 2), which encodes for a FKBP-type peptidyl-prolyl isomerase
(PPI_FKBP; Os02g0760300), strictly cosegregates with apomixis. Our objective here was to
start characterizing the expression of the ACL-derived PPI_FKBP, to enable further repro-
ductive functional analysis. Eight (8) transcripts showing homology to C932 were retrieved
from reference reproductive transcriptomes of the species. Five (5) of them, all derived
from the same gene (isogroup) and encoding functional proteins, were detected in sexual
genotypes. Other 3, originated from different genes (isogroups) and displaying dissimilar
structures, were detected in apomictic transcriptomes. One of the apomictic sequences
encodes for a functional protein, another one derives from a pseudogene, and the last one is
a chimeric transcript, with homology to PPI_FKBP and DNAJ (the adjacent gene in the rice
genome) (PPIQUIM). In experimental mapping, only PPIQUIM resulted genetically linked
to the ACL. However, genomic sequencing indicated that PPI_FKBP- and DNAJ-derived
exons are separated by a long intergenic region. Moreover, PPIQUIM was exclusively
amplified from floral RNA of apomictic plants. Our results indicate that PPIQUIM is
specifically expressed from the ACL and would be a product of intersplicing. Its functional
role remains to be determined.
3.1.7. Disclosing the Molecular Link between Apospory and Diplospory
Garbus I 1, Podio M 2, Echenique V 1, Pessino SC 2,*
1 Centro de Recursos Naturales de la Zona Semiárida (CERZOS-CONICET-UNS),
Bahía Blanca Argentina; 2 Instituto de Investigaciones en Ciencias Agrarias de Rosario
(IICAR-CONICET-UNR), Zavalla, Argentina. * pessino@iicar-conicet.gob.ar
Gametophytic apomixis forms seeds with clonal embryos identical to the mother
plant through two different mechanisms, namely apospory and diplospory, both of them
involving the formation of non-reduced megagametophytes within the ovule. These non-
reduced embryo sacs are originated from companion nucellar cells (apospory) or the
megaspore mother cell, after absence/failure of meiosis (diplospory). In both paths the
non-reduced egg cells produce embryos through parthenogenesis. Our hypothesis here was
that, at least for some candidate genes, apomeiosis and parthenogenesis associate, respec-
tively, with contrasting or identical representation patterns in aposporous vs. diplosporous
differential mRNA expression comparisons. The rationale supporting this proposition is
that in aposporous and diplosporous plants apomeiosis might involve some common genes
under an opposite spatio-temporal regulation pattern (OE transcripts), while parthenogene-
sis should be identically activated in both reproductive types (IE candidates). We compared
two sets of Roche/454 sequences differentially expressed in reproductive organs of sexual
vs. apomictic plants of Paspalum notatum (aposporous) and Eragrostis curvula (diplosporous)
from pre-meiosis to anthesis, to identify OE and IE transcripts. Then, the selected sequences
were investigated in TruSeq/Hiseq Illumina RNA floral libraries constructed at different
Plants 2021, 10, 565 9 of 17
reproductive stages. We found 89 opposite expression transcripts exclusively represented
at pre-meiosis and 66 equal expression transcripts occurring at anthesis only. These can-
didate genes were used to produce String interaction networks with others previously
related with apomeiosis and parthenogenesis, and their location is being mapped within
the Paspalum and Eragrostis genomic ACL (apomixis controlling loci). Functional analysis
of selected sequences is at work.
3.1.8. Genes Modulating the Increase of Sexuality in the Facultative Apomictic Grass
Eragrostis Curvula under Water Stress Conditions
Selva JP *, Zappacosta D, Carballo J, Rodrigo JM, Bellido A, Gallo CA, Gallardo J,
Echenique V
Centro de Recursos Naturales de la Zona Semiárida (CERZOS-CONICET-UNS), Bahía
Blanca Argentina. * jpselva@cerzos-conicet.gob.ar
Previous reports in Eragrostis curvula, a diplosporous apomictic forage grass, showed
that facultative apomictic genotypes reduce the proportion of apomictic embryo sacs
under stressful conditions like in vitro culture and drought. Here, we report the cytoem-
bryological and transcriptomic analysis of inflorescences of facultative apomictic plants
under control and drought stress treatment in order to identify the mechanisms regu-
lating the switch from sexual to asexual reproduction. Embryo sacs from control and
stressed plants (161 and 172, respectively) were analyzed, and RNA-Seq Illumina libraries
with three biological replicates from inflorescences of control and stressed plants were
sequenced. The percentage of sexual embryo sacs increased from 4 to 24% and 501 out
of 201,011 transcripts were differentially expressed (DE) between control and stressed
plants (151 upregulated and 350 downregulated in stressed plants). Out of these, 380 were
annotated and analyzed using BLAST2GO and KEGG. DE transcripts were compared
with previous transcriptomes where apomictic and sexual genotypes were contrasted. The
results point as candidates to transcripts related to methylation, ubiquitination, hormone
and signal transduction pathways, transcription regulation, and cell wall biosynthesis,
some acting as a general response to stress, and some that are specific to the reproductive
mode. We suggest that a DNA glycosylase EcROS1-like could be demethylating, thus
de-repressing a gene or genes involved in the sexual pathway. Many of the other DE
transcripts could be part of a complex mechanism that regulates apomixis and sexuality
in this grass, the ones in the intersection between control/stress and apo/sex being the
strongest candidates.
3.2. Genomics and Epigenomics of Apomixis
3.2.1. Mapping Apomixis in the Plicatula Group of Paspalum through Genotyping
by Sequencing
Wagner AW 1,*, Ortiz JPA 2, Espinoza F 1
1 Instituto de Botánica del Nordeste (IBONE), CONICET, FCA UNNE, Corrientes,
Argentina; 2 Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR-CONICET-
UNR), Zavalla, Argentina. * werfilwagner@gmail.com
In the Paspalum, apomixis (asexual reproduction via seeds) is controlled by a single-
dominant complex locus (ACL). The Plicatula group includes species either with diploid
sexual (2n = 2x = 20) and apomictic tetraploid (2n = 4x = 40) cytotypes, and with exclusively
polyploid (mostly tetraploid) races. While genetic linkage maps in P. notatum and P. simplex
revealed non-recombinant ACLs, initial AFLP mapping in P. guenoarum (Plicatula) revealed
a recombinant ACL. This work aims at building a dense genetic linkage map of tetraploid
Plicatula spp. through genotyping by sequencing (GBS), localizing the ACL and facilitating
both identification and positional cloning of the genes governing apomixis. The mapping
population (n = 82; 52 sexual and 32 apomict F1 plants) derives from a cross between
P. plicatulum 4-PT (a 4× colchicine-induced sexual plant)× P. guenoarum GR19 (a 4× natural
apomict individual). Genomic DNA was digested with ApeKI and used for preparing
Illumina NextSeq 550 libraries. A total of 366 million reads (75 bp single-end; 4.35 million
reads/sample on average) were obtained. Initially, the STACKS and TASSEL_UNEAK
Plants 2021, 10, 565 10 of 17
softwares were used for de novo SNP discovery, but failed to identify relevant markers.
Then, the TASSEL5GBSV2 pipeline was used with Setaria viridis, Zea mays, and P. notatum
(draft) genomes as references and produced, respectively, 9,264; 2,365, and; 10,711 single-
dose markers. Genotypes related with the ACL (Aaaa and aaaa for apomictic and sexual
plants, assuming a dominant simplex control) were assigned to each F1 in the GBS data
matrix. Linkage analyses are ongoing using JoinMap 4.0 and a pseudo-test cross model.
3.2.2. Sequencing Paspalum Genomes
Leblanc O 1,*, Pupilli F 2, Albertini E 3, Espinoza F 4, Pessino, SC 5, Ortiz JPA 5
1 DIADE, Univ Montpellier, CIRAD, IRD, Montpellier, France; 2 Institute of Biosciences
and Bioresources, Research Division of Perugia, National Research Council, Perugia, Italy;
3 Department of Agricultural, Food and Environmental Science, University of Perugia,
Perugia, Italy; 4 Instituto de Botánica del Nordeste (IBONE), CONICET, FCA UNNE,
Corrientes, Argentina; 5 Instituto de Investigaciones en Ciencias Agrarias de Rosario
(IICAR-CONICET-UNR), Zavalla, Argentina. * olivier.leblanc@ird.fr
Paspalum notatum is a forage grass from South American subtropical regions. Diploid in-
dividuals (2n = 20) are sexual plants, while polyploid individuals reproduce through
aposporous apomixis. In grasses, apomixis is genetically controlled by a single non-
recombinant heterochromatic genomic region, the Apomixis Controlling Region (ACR)
which nature and function remain elusive. Our objective is to generate genomic sequences
of sexual and apomictic P. notatum individuals to understand ACR emergence and evolu-
tion; to identify genes governing important agronomical traits, including apomixis; and to
improve genomic selection in breeding programs. To achieve this, we selected one diploid
genotype (R1) and two tetraploid genotypes reproducing through obligate (Q4188) and fac-
ultative (Q3664) apomixis. Genomic DNA was sequenced using Illumina (R1) and Oxford
Nanopore (R1, 32 Gb; Q4188, 22 Gb; Q3664, 21 Gb) technologies. K-mer analyses using
short reads confirmed flow cytometrical analyses for R1 genome size (~600 Mbp) and high
heterogozigosity. Here we report on the quality metrics of R1 genomic assemblies generated
by combining the output of several long-read assemblers (wtdbg2, Shasta, Flye, miniasm,
and smartdenovo) and Bionano optical maps: size, N50, contiguity, BUSCO completeness,
coverage distribution. The best hybrid scaffolding using a 2300-contig smartdenovo as-
sembly rendered 53 scaffolds (795.27 Mbp, N50 33.54 Mbp, >95% BUSCO completeness).
However, a partial representation of heterozygous regions and numerous, dispersed gaps
still hinder structural variation analyses. We anticipate that a new set of ONT sequences
and the use of tools for detecting and purging haplotypes will allow in a short time the
completion of the assembly of R1 genome haplotypes.
3.2.3. Identification of a Genomic Region Linked to Apomixis in Eragrostis Curvula
Carballo J 1,*, Gallardo J 1,*, Gallo CA 1, Selva JP 1, Garbus I 1, Zappacosta D 1,
Albertini E 2, Caccamo M 3, Echenique V 1
1 Centro de Recursos Naturales de la Zona Semiárida (CERZOS-CONICET-UNS),
Bahía Blanca Argentina; 2 Department of Agricultural, Food and Environmental Science,
University of Perugia, Perugia, Italy; 3 NIAB, Cambridge, Reino Unido. * These au-
thors contributed equally to this work: jcarballo@cerzos-conicet.gob.ar, jgallardo@cerzos-
conicet.gob.ar
Eragrostis curvula is a forage grass with n = 10 and ploidy levels ranging from 2× to
8×. This grass has become a model for the study of diplosporous apomixis, an asexual
reproduction by seeds in which the progeny is genetically identical to the mother plant.
To identify the genomic regions and the genes involved in apomixis, the genome of the
diploid sexual cultivar Victoria was sequenced using a combination of approaches (PacBio,
Chicago and Hi-C) and contrasted against the region identified by high density mapping.
The final assembly render an N50 of ~43 Mb and 1143 contigs being completely assembled
the seven longest full chromosomes according to the synteny analyses. The annotation
identified 56,469 genes and 28.7% of repetitive elements. On the other hand, a high
Plants 2021, 10, 565 11 of 17
saturated linkage map at tetraploid level was constructed using both traditional (AFLP
and SSR) and high-throughput molecular markers (GBS-SNP) and a locus controlling
diplospory and putative regulatory regions affecting the expressivity of the trait were
identified. The four markers linked to apomixis in the E. curvula linkage map were aligned
to Victoria, identifying a 10 Mb region. Furthermore, using a transcriptomic approach,
genes up and downregulated in the apomictic genotypes were identified, including genes
that could be repressing sexuality or promoting apomixis. The identification of the region
linked to apomixis, its expression and regulation could allow to better understand some
features of this interesting trait and it paves the way to sequence and assemble the complete
region in the more complex polyploid genotypes.
3.2.4. A Deeper Understanding of Differential Sense/Antisense RNA Representation in
Reproductive Organs of Sexual and Apomictic Paspalum Notatum
Podio M *, Colono C *, Siena L, Ortiz JPA, Pessino SC
Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR-CONICET-UNR),
Facultad de Ciencias Agrarias, Universidad Nacional de Rosario, Campo Experimental
Villarino, Zavalla, Santa Fe, Argentina. * These authors contributed equally to this work:
podio@iicar-conicet.gob.ar, colono@iicar-conicet.gob.ar
The selection of apomixis genes to be used as breeding/research tools requires de-
tailed characterization of the expression landscape across multiple developmental stages.
Our group established Roche 454/FLX+ reference floral transcriptomes from sexual and
apomictic Paspalum notatum biotypes and used these solid frames to assist the assembly
of 24 extensive TruSeq®/Hiseq Illumina libraries, covering in triplicate four reproductive
steps (pre-meiosis, meiosis, post-meiosis, anthesis). Moreover, de novo assemblies were
constructed with Trinity to complete an integrative global transcriptome. For differential
expression analysis, RNA-seq reads were analyzed with the Kallisto v.0.44.0 software to
determine transcript counts and abundances. These analysis allowed us to: (1) identify
sequences differentially expressed in apomictic and sexual biotypes, which were consis-
tently differential on the course of development or otherwise stage-specific; (2) characterize
some differentially expressed transcript clusters (particularly transcription factors of the
AP2, ARF, MYB, and WRKY groups, as well as hormone-pathways controllers of the auxin,
jasmonate, and cytokinin families); (3) detect a number of antisense sequences differentially
modulated between reproductive modes; and (4) gain knowledge on the expression of a
group of transcripts that had been previously associated with apomixis. Currently, we are
using the Illumina libraries to identify transcripts expressed from the apomixis control-
ling locus (ACL), whose sequence is partially available through the Paspalum genome
sequencing initiative.
3.2.5. Is Apomictic Seed Development Influenced/Controlled by Epigenetic Factors?
Marconi G 1, Soliman M 2,3, ZAappacosta D 4, Di Marsico M 1, Bocchini M 1, Gallardo J 4,
Delgado L 2,3, Echenique V 4, Albertini E 1,*
1 Department of Agricultural, Food and Environmental Sciences, University of Pe-
rugia, Perugia, (Italy); 2 Instituto de Investigaciones en Ciencias Agrarias de Rosario
(IICAR-CONICET-UNR), Zavalla, Argentina; 3 Facultad de Ciencias Agrarias, Universi-
dad Nacional de Rosario, Zavalla (Argentina); 4 Centro de Recursos Naturales de la Zona
Semiárida (CERZOS-CONICET-UNS), Bahía Blanca, Argentina. * emidio.albertini@unipg.it
Several lines of evidence suggest that transitions during reproduction and early seed
development are epigenetically regulated by dynamic changes in chromatin state. More-
over, deregulation of key developmental steps in sexual processes are thought to cause
apomixis, and supporters of this hypothesis justify it based on the coexistence of sex and
apomixis in the same individual. For example, some authors found that DNA methylation
deregulation in reproductive cells induce apomeiosis-like phenotypes suggesting that
specialization of a DNA methylation pathway acts upon germline or germline associated
cells. With this aim in mind, we decided to investigate DNA methylation differences
between apomictic and sexual genotypes of two species, Paspalum rufum and Eragrostis
Plants 2021, 10, 565 12 of 17
curvula. High-throughput DNA sequencing technologies have enabled the measurement
of cytosine methylation on a genome-wide scale. Many technologies have been devel-
oped over the past decade to measure DNA methylation. MCSeEd (Methylation Content
Sensitive Enzyme ddRAD) is a reduced-representation, reference-free, cost-effective ap-
proach for characterizing whole genome methylation patterns across different methylation
contexts (CG, CHG, CHH, 6 mA) that we have recently developed at the University of
Perugia. DNA from triplicate panicle samples of contrasting reproductive mode materials
were digested with enzymes sensitive to DNA methylation (AciI, PstI, EcoT22I, and DpnII,
for the CG, CHG, CHH and 6 mA contexts, respectively), and libraries were generated and
sequenced in Illumina platform. Several differentially methylated genomic regions were
found and associated to annotated genes that were classified with the BLAST2GO software.
Several genes already linked to apomixis (i.e., SERK, APOSTART) were found to be both
differentially methylated and differentially expressed.
3.2.6. Epigenetic Marks Associated with Apospory Expressivity during Floral
Development of Diploid Paspalum Rufum Cytotype
Delgado L 1,*, Soliman M 1, Podio M 1, Marconi G 2, Di Marsico M 2, Ortiz JPA 1,
Albertini E 2
1 Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR-CONICET-
UNR), Zavalla, Argentina; 2 Department of Agricultural, Food and Environmental Sciences
University of Perugia, Perugia, Italy. * luciana.delgado@conicet.gov.ar
Apomixis is an asexual reproduction pathway through seeds that generates clonal
progenies. It was proposed to derive from the deregulation of genes involved in sexuality
by genetic/epigenetic mechanisms. Paspalum rufum grass forms a multiploid complex
with self-sterile sexual diploid and self-fertile apomictic tetraploid cytotypes but some
diploid genotypes produce aposporous embryo sacs and clonal seeds. Moreover, varia-
tion in apospory expressivity was detected within experimentally obtained diploid families.
Here we compare the relative methylation levels between floral libraries of full-sib diploid
P. rufum genotypes exhibiting low and high apospory expressivity. Methylation Content
Sensitive Enzyme ddRAD (or MCSeEd) strategy, without reference genome, was applied
in two developmental stages, pre-meiosis/meiosis and post-meiosis and at three different
contexts (CG, CHG and CHH). Heatmaps and principal component analysis of the relative
methylation changes clearly discriminated between reproductive behavior at both develop-
mental stages and for almost all the methylation contexts. P. notatum floral transcriptome
was queried by differential methylated contigs (DMCs), revealing 14% of homology, al-
most half of which were differentially expressed between apomictic and sexual samples
of P. notatum. BLAST searches over public databases allowed the identifications of DMCs
homologous to genes involved in flower growth, development and also to many genes
and genomic regions previously associated to apomictic development. In silico mapping
on Setaria italica genome showed a high proportion of DMCs aligning on genomic regions
previously associated with apomixis. This work provides evidence of the presence of dif-
ferential methylation levels associated with variation in apospory expressivity in a diploid
grass species.
3.2.7. Epigenetic Mechanisms Involved in Diplospory Regulation in Weeping Lovegrass
Zappacosta DC 1,2,*, Garbus I 1,3,*, Selva JP 1, Carballo J 1,2, Pasten MC 1, Gallardo
JA 1,2, Bellido AM 1, Marconi G 1,4, Albertini E 1,4, Echenique V 1,3
1 Centro de Recursos Naturales de la Zona Semiárida (CERZOS-CONICET-UNS),
Bahía Blanca, Argentina; 2 Depto. Agronomía-UNS Bahía Blanca, Argentina; 3 Depto.
Ciencias de la Salud-UNS Bahía Blanca, Argentina; 4 Università degli Studi di Perugia, Dip.
di Scienze Agrarie, Alimentari e Ambientali, Perugia, Italy. * These authors contributed
equally to this work: dczappa@criba.edu.ar, igarbus@criba.edu.ar
Weeping lovegrass (Eragrostis curvula) is a forage grass with a particular diplosporous
apomixis where meiosis is absent and sexual and apomictic seeds have equal embryo:endosperm
ploidy ratio. Several lines of evidence show that epigenetic regulation is involved in the
Plants 2021, 10, 565 13 of 17
expressiveness of the trait, accounting for the variable expression between plants and for
the increase of the frequency of sexual pistils in facultative genotypes triggered by biotic
and abiotic stresses. The aim of this study was to associate differences in the reproductive
mode to epigenetic mechanisms given by DNA methylation and miRNAs regulation of
gene expression. Firstly, the Methylation Content Sensitive Enzyme ddRAD (MCSeEd) was
used to detect hypermethylated and hypomethylated positions and further associate them
with apomictic (full and facultative) and sexual genotypes. The distribution of differentially
methylated positions across genes at CG and 6mA shows a peak around the transcript
start and transcript termination sites, hence regulating gene expression mainly through
the incorporation of methyl groups on these positions. Gene ontology analysis reveals
terms associated to auxins, clathrins, and kinases previously observed in apomictic species.
Moreover, some genes differentially expressed related to the reproductive pathway, could
be linked to the methylation status in the present work. Regarding miRNAs, a target
analysis allowed the identification of a MADS-box transcription factor and a transposon
repressed in the sexual genotype through specific miRNA-mRNA interactions. Addi-
tional miRNA-mRNA pairs specific for sexual or apomictic genotypes were identified in a
degradome-based analysis conducted using Oryza sativa database, reinforcing the concept
of apomixis resulting from sexual pathway deregulation.
3.3. Agronomic Traits and Breeding Approaches in Apomictic Forage Grasses
3.3.1. Flowering Induction in Paspalum plicatulum Michx, a Sexual Tetraploid and
Sexual Plant
Novo PE 1,*, Ruiz Díaz GS 1, Quarin CL 1, Vidoz ML 1,2, Espinoza F 1,2
1 Facultad de Ciencias Agrarias, Universidad Nacional del Nordeste (FCA-UNNE),
Corrientes, Argentina; 2 Instituto de Botánica del Nordeste (IBONE-CONICET), Corrientes,
Argentina. * patriciaenovo@gmail.com
Paspalum plicatulum is an experimental sexual autotetraploid plant (4 × S) obtained
by colchicine doubling chromosomes from a wild 2× plant. 4 × S had already produced
interspecific hybrids in crossing with tetraploid apomictic species (4 × A) of the Plicatula
group. However, the 4 × S plant blooms in early summer and there are some 4 × A
species in this group which bloom in late April, preventing crossbreeding. The objective
of this study was to delay the flowering of 4 × S by controlling the photoperiod and
temperature and to hybridize with 4 × A species of the Plicatula group that flower in April.
The experiments were carried out in a chamber with controlled light (14 h) and temperature
(25 ◦C ± 2◦) and were repeated twice. We used 16 4 × S clones in a 4-treatment design: (1)
control (in greenhouse, natural light), (2) light intensity of 170 µmol m−2 s−1 of; (3) light
intensity of 350 µmol m−2 s−1; and (4) light intensity of170 µmol m−2 s−1 + 25 µg GA3 en
10 µL of ethanol 95% (v/v). The control did not flower, while all the chamber treatments
started flowering at 90 days. Using these plants as pistillate, hybrids were obtained after
crossing with cv. Cambá and line U44 of P. atratum and with cv. Chané of P. guenoarum.
Thus, the delay in flowering of the 4 × S plant allowed obtaining new interspecific hybrids
to be achieved within the Plicatula group of Paspalum. This will permit expanding the
use of germplasm from other apomictic species in the genetic improvement program for
native forages.
3.3.2. Heterosis in Tetraploid Paspalum notatum: Evaluation of Its Occurrence, Prediction,
and Breeding Techniques
Marcón F *, Martínez EJ, Brugnoli EA, Zilli AL, Acuña CA
Instituto de Botánica del Nordeste, CONICET, Facultad de Ciencias Agrarias, UNNE,
Corrientes, Argentina. * fmarcon91@gmail.com
Paspalum notatum Flüggé is one of the main components of the South American
grasslands. At present, hybridization is the most popular breeding technique in the
species, and its goal is to obtain superior apomictic hybrids. Occurrence of heterosis in
tetraploid P. notatum hybrid progenies in relationship with the genetic distance among
parents was determined. Secondly, recurrent selection based on combining ability (RSCA)
Plants 2021, 10, 565 14 of 17
and recurrent phenotypic selection (RPS) were evaluated in a sexual synthetic tetraploid
population (SSTP). Genetic distances among parents with different origins were determined
using molecular markers. Group of crosses among parents with low, intermediate and
high genetic distances were identified. The progeny obtained was evaluated for a series
of agronomic and morphological traits. There was a significant relationship between
genetic distances among parents and heterosis mainly for forage yield. For this reason,
molecular markers could be used as a tool to predict the occurrence of heterosis for this trait.
On the other hand, two new sexual populations were created by RSCA and RPS. Sexual
genotypes obtained by both methods were crossed with superior apomictic genotypes.
Both methods allowed us to obtain hybrid progenies that were evaluated for summer, fall,
and spring growth. RPS progenies exhibited greater summer growth and heterosis than
RSCA progenies, although for fall and spring growth were similar. RPS was equal or more
efficient than RSCA since it allowed obtaining equal or more genetic progress and heterosis.
The breeding techniques used in this work allow exploiting the heterosis in tetraploid
P. notatum.
3.3.3. Advances in the Breeding of Paspalum Notatum towards a New Forage Cultivar
Acuña CA *, Zilli AL, Brugnoli EA, Marcón F
Instituto de Botánica del Nordeste, CONICET, Facultad de Ciencias Agrarias, UNNE,
Corrientes, Argentina. * caalac77@gmail.com
There is a need for developing forage cultivars for subtropical areas, which combine
warm summers with cold winters, and marked variation in photoperiod. Paspalum notatum
is an apomictic grass adapted to these transitional climate zones. The objective was to de-
scribe the advances of the Paspalum notatum breeding program in Argentina. Crosses were
made between a few sexual clones and several apomictic ecotypes collected throughout
the New World. Segregation for mode of reproduction varied between 1:1 to 1:7.4 between
apomictic and sexual within families, with a mean of 1:3.2. A high variation was observed
for apomixis expressivity within the apomictic progeny, with most hybrids exhibiting very
low (less than 10% of the ovules bearing aposporous embryo sacs) or high expressivity
(more than 70%). Only the highly apomictic hybrids were evaluated in the field as spaced
plants for two years and sward plots for three years, especially considering frost tolerance,
and growth during the cool season. Currently, five selected hybrids are being evaluated
in three locations in northeastern, and one in central Argentina. A grazing trial is also
being conducted to determine the grazing tolerance of these 5 hybrids. The genetic stability
across cropping cycles will also be determine using molecular markers. A superior highly
apomictic genotype is expected to be selected in two years.
3.3.4. Review of the Breeding Process of Apomictic Hybrids in Forage Grasses at the
Research Center for Tropical Agriculture—CIAT
Castiblanco V *
International Center for Tropical Agriculture (CIAT), Km 17, Recta Cali-Palmira,
Palmira, Valle del Cauca, Colombia. * v.castiblanco@cgiar.org
The forages breeding program at CIAT has a 45-year history, and it aims to improve the
livelihoods of poor crop-livestock producers in the tropics, by intensifying production while
reducing the environmental footprint. Furthermore, adaptation of forages to droughts
and waterlogging related to global climate change is a priority to secure animal nutrition.
The forage breeding program of CIAT aims to tackle this by developing hybrids with
desired traits that are targeted for different environments. To date, our program works
on three breeding pipelines: Urochloa interspecific, Urochloa humidicola and Megathyrsus
maximus (formerly known as Brachiaria interspecific, Brachiaria humidicola„ and Panicum
maximus). The U. interspecific breeding pipeline has developed interspecific hybrids for sub-
humid tropics that are adapted to extreme biotic stress (e.g., spittlebug insects) and abiotic
conditions (e.g., acid soils), with improved quality and maximum biomass production.
This pipeline released in 2001, the first apomictic hybrid in the field of tropical forages and
exhibits the most successful hybrid in the market currently: Mulato II. To date, six apomictic
Plants 2021, 10, 565 15 of 17
hybrids are available in the market. In addition, we are preparing products for the humid
tropics (U. humidicola) and another for highly intensified livestock systems (M. maximus).
We presented an overview of the genotyping tools (e.g., marker-assisted selection for
apomixis), phenotyping tools (e.g., spittlebug screening), as well as the integration of
these approaches into a recurrent selection scheme, enabling the permanent release of
high-performing hybrids with constant genetic gain.
3.3.5. Advances in the Breeding of Panicum maximum in Brazil
Jank LJ *, Santos, MF, Valle CB do, Carvalho SB, Simeão RM, Raposo A, Chiari L,
Meirelles K
Embrapa Beef Cattle, Campo Grande, MS, Brazil. * liana.jank@embrapa.br
Breeding of Panicum maximum Jacq. (syn. Megathyrsus maximus (Jacq.) B.K.Simon
& S.W.L.Jacobs) in Brazil began in 1982 with the introduction of the ORSTOM (Institut
de Recherche pour le Développement) germplasm collected in East Africa and composed
of 426 apomictic accessions and many sexual tetraploid plants. Field evaluation of the
apomictic accessions in Campo Grande, MS, Brazil, led to the selection of 25 which were
evaluated in seven regions. The best ones were evaluated under grazing and released
as cv. Tanzânia. Mombaça and Massai in 1990, 1993, and 2001, respectively. Nowadays,
they occupy around 20 million hectares in Brazil and respond for about 96% of the com-
mercialized seeds of the species. Recently, other three cultivars were released. BRS Zuri is
a tall wide-leaved high yielding high-quality cultivar, which resulted in 13% higher animal
gain/area than Tanzânia and Mombaça in the Amazon and Cerrado biomes. BRS Tamani
is a short, narrow-leaved plant which resulted in 10–16% higher gain/animal than Massai
due to 6–20% higher crude protein and digestibility. BRS Quênia is medium-sized, medium-
leaved, high yielding high-quality cultivar which resulted in 9% higher animal gains/area
than Tanzânia in the Amazon biome and 17% higher than Mombaça in the Cerrado biome.
Advances in genetic information were obtained from the evaluation of over 8000 hybrids
from crosses between 10 divergent sexual plants and 10 divergent apomictic accessions
on two levels of soil fertility. Advances in the program include high-resolution linkage
map and genomic selection with allele dosage, large-scale phenotyping, and obtention of
core collections.
3.3.6. Reproductive Behavior of the Apomictic Paspalum Notatum Hybrid Cultivar
Boyero-UNNE Growing at Field Conditions in the Argentina Temperate Region
Anibalini VA *, Busnelli V, Balaban D, Soliman M, Martín, B, Delgado L, Ortiz JPA
Instituto de Investigaciones en Ciencias Agrarias de Rosario (IICAR-CONICET-UNR),
Zavalla, Argentina. * veronica.anibalini@unr.edu.ar
Paspalum notatum cv. Boyero-UNNE is an apomictic-hybrid cultivar developed at FCA-
UNNE, Argentina. Here we evaluated seed development and phenotypic/reproductive
stability through successive generations of Boyero-UNNE in the argentine temperate region
(pampas). Plots were established at the FCA-UNR, Zavalla, Argentina. The development
of seeds was examined by collecting 20 inflorescences every 3 days during the flowering
period (21 days in total) and observing ≥50 spikelets/plant with a binocular microscope.
Proportions of small fertilized ovaries (SFO), immature caryopses (IC), filled caryopses (FC),
necrotic ovaries (NO), and empty spikelets (ES) were scored. The stability of vegetative
and reproductive traits was evaluated in three F1 families (seeds collected in 2016, 2017,
2018) by measuring plant height (PH), tiller number (TN), stem length (SL), bunch length
(BL) and percentages of ovules carrying aposporous sacs (% OAES), meiotic sacs (% OMES)
and aposporous + meiotic sacs (% OMIX). The vegetative traits were also examined in
the progeny of each F1 family. Seed development studies showed 18% SFO, 18% IC, 38%
FC, 24% NO, and 2% ES. Non-significant differences were observed in vegetative traits
across families and generations. The reproductive characterization showed, on average,
54.7% OAES, 15.4% OMES and 29.9% OMIX (total apomixis capacity: % OAES +% OMIX
= 84.6%). Our results indicated that cv. Boyero-UNNE can form caryopses in up to 74%
of the spikelets (18% SFO, 18% IC, and 38% FC). Moreover, considering that original
Plants 2021, 10, 565 16 of 17
Boyero-UNNE reports notify a total apomictic capacity of 86–93%, both vegetative and
reproductive traits can be considered stable across generations.
4. Conclusions and Remarks
Despite the online format imposed by the COVID19 pandemic, the 2020 edition of the
Series of Seminars on Advances in Apomixis Research was a great success in strengthening
the growing network of scientists involved in apomixis and supported by the European
Union H2020 Programme and in providing an opportunity for students and young and
senior researchers to share their experience and work.
Biological features of apomicts (e.g., high heterozygosity, polyploidy, resistance to
genetic transformation [21]) have long prevented the use of the new “omics” and imaging
technologies during their early stages and, most recent advances in the genetics and the
molecular control of apomixis have arisen from sexual model species, such as Arabidopsis,
maize, and rice. Among the best examples are the epigenetic control acting throughout
reproductive development [22] and the role of key transcription factors in the acquisition
of parthenogenetic competences (i.e., BABY BOOM [23,24]). However, as illustrated by the
abstracts reported here, increasing accessibility to modern analytical tools for genome-wide
structural and expression studies and to state-of-the-art confocal microscopy is changing
profoundly the field by expanding our knowledge about the structure and the functioning
of natural apomicts genomes, and by providing novel candidate functions and pathways
for apomixis. Results are expected to fuel our understanding of the reproductive biology
of apomicts and, therefore, they could contribute efficiently to fine-tune synthetic paths
or to improve plant breeding procedures. The main perspective of the MAD project is
to resolve candidate mechanisms involved in the regulation of the developmental shift
driving sexual reproduction into apomixis through effective sharing of biological resources,
expertise, and knowledge gathered from 12 laboratories internationally recognized for
their contribution to apomixis research.
Supplementary Materials: The following are available online at https://www.mdpi.com/2223-774
7/10/3/565/s1, Table S1: MAD kick-off meeting participants.
Author Contributions: V.E. and O.L. co-organized the conference; all authors compiled and format-
ted abstracts, and organized and edited the proceedings. O.L. wrote Section 2. D.A. prepared the
figure. All authors have read and agreed to the final version prior to submission. All authors have
read and agreed to the published version of the manuscript.
Funding: This report received no external funding.
Institutional Review Board Statement: Not applicable.
Informed Consent Statement: Not applicable.
Data Availability Statement: No new data were created or analyzed in this study. Data sharing is
not applicable to this article.
Acknowledgments: The authors wish to thank the speakers for their contribution and all participants
for exciting discussions.
Conflicts of Interest: The authors declare no conflict of interest.
References
1. Thiault, L.; Mora, C.; Cinner, J.E.; Cheung, W.W.L.; Graham, N.A.J.; Januchowski-Hartley, F.A.; Mouillot, D.; Sumaila, U.R.;
Claudet, J. Escaping the perfect storm of simultaneous climate change impacts on agriculture and marine fisheries. Sci. Adv. 2019,
5, eaaw9976. [CrossRef]
2. Steinwand, M.A.; Ronald, P.C. Crop biotechnology and the future of food. Nat. Food 2020, 1, 273–283. [CrossRef]
3. Foley, J.A.; Ramankutty, N.; Brauman, K.A.; Cassidy, E.S.; Gerber, J.S.; Johnston, M.; Mueller, N.D.; O’Connell, C.; Ray, D.K.; West,
P.C.; et al. Solutions for a cultivated planet. Nature 2011, 478, 337–342. [CrossRef] [PubMed]
4. Jacquier, N.M.A.; Gilles, L.M.; Pyott, D.E.; Martinant, J.P.; Rogowsky, P.M.; Widiez, T. Puzzling out plant reproduction by haploid
induction for innovations in plant breeding. Nat. Plants 2020, 6, 610–619. [CrossRef]
Plants 2021, 10, 565 17 of 17
5. Vijverberg, K.; Ozias-Akins, P.; Schranz, M.E. Identifying and engineering genes for parthenogenesis in plants. Front. Plant Sci.
2019, 10, 128. [CrossRef] [PubMed]
6. Nogler, G.A. (Ed.) Gametophytic Apomixes; Springer: Berlin, Germany, 1984.
7. León-Martínez, G.; Vielle-Calzada, J.P. Apomixis in flowering plants: Developmental and evolutionary considerations. Curr. Top.
Dev. Biol. 2019, 131, 565–604. [CrossRef]
8. Pennizi, E. Sowing the seeds for the ideal crop. Science 2010, 327, 802–803. [CrossRef]
9. Lenaerts, B.; Collard, B.C.Y.; Demont, M. Review: Improving global food security through accelerated plant breeding. Plant Sci.
2019, 287, 110207. [CrossRef] [PubMed]
10. Sailer, C.; Schmid, B.; Grossniklaus, U. Apomixis allows the transgenerational fixation of phenotypes in hybrid plants. Curr. Biol.
2016, 26, 331–337. [CrossRef]
11. Hanna, W.W.; Bashaw, E.C. Apomixis: Its Identification and Use in Plant Breeding. Crop Sci. 1987, 27, 1136–1139. [CrossRef]
12. Vielle Calzada, J.P.; Crane, C.F.; Stelly, D.M. Apomixis: The asexual revolution. Science 1996, 274, 1322–1323. [CrossRef]
13. Ozias-Akins, P.; Conner, J.A. Clonal Reproduction through Seeds in Sight for Crops. Trends Genet. 2020, 36, 215–226. [CrossRef]
14. Koltunow, A.M.; Grossniklaus, U. Apomixis: A developmental perspective. Annu. Rev. Plant Biol. 2003, 54, 547–574. [CrossRef]
[PubMed]
15. Grimanelli, D.; Leblanc, O.; Perotti, E.; Grossniklaus, U. Developmental genetics of gametophytic apomixis. Trends Genet. 2001,
17, 597–604. [CrossRef]
16. Ozias-Akins, P.; van Dijk, P.J. Mendelian genetics of apomixis in plants. Annu. Rev. Genet. 2007, 41, 509–537. [CrossRef] [PubMed]
17. Nakajima, K. Be my baby: Patterning towards plant germ cells. Curr. Opin. Plant Biol. 2018, 41, 110–115. [CrossRef]
18. Pinto, S.C.; Mendes, M.A.; Coimbra, S.; Tucker, M.R. Revisiting the female germline and its expanding toolbox. Trends Plant Sci.
2019, 24, 455–467. [CrossRef] [PubMed]
19. Leblanc, O.; Grimanelli, D.; Hernandez-Rodriguez, M.; Galindo, P.A.; Soriano-Martinez, A.M.; Perotti, E. Seed development and
inheritance studies in apomictic maize-Tripsacum hybrids reveal barriers for the transfer of apomixis into sexual crops. Int. J. Dev.
Biol. 2009, 53, 585–596. [CrossRef] [PubMed]
20. Singh, M.; Conner, J.A.; Zeng, Y.-J.; Hanna, W.W.; Johnson, V.E.; Ozias-Akins, P. Characterization of apomictic BC7 and BC8
pearl millet: Meiotic chromosome behavior and construction of an ASGRcarrier. chromosome-specific library. Crop Sci. 2010, 50,
892–902. [CrossRef]
21. Ortiz, J.P.A.; Pupilli, F.; Acuña, C.A.; Leblanc, O.; Pessino, S.C. How to Become an Apomixis Model: The Multifaceted Case of
Paspalum. Genes 2020, 11, 974. [CrossRef]
22. Grimanelli, D. Epigenetic regulation of reproductive development and the emergence of apomixis in angiosperms. Curr. Opin.
Plant Biol. 2012, 15, 57–62. [CrossRef] [PubMed]
23. Conner, J.A.; Ozias-Akins, P. Apomixis: Engineering the Ability to Harness Hybrid Vigor in Crop Plants. Methods Mol. Biol. 2017,
1669, 17–34. [CrossRef] [PubMed]
24. Khanday, I.; Skinner, D.; Yang, B.; Mercier, R.; Sundaresan, V. A male-expressed rice embryogenic trigger redirected for asexual
propagation through seeds. Nature 2019, 565, 91–95. [CrossRef] [PubMed]