Development of markers for the use of the PEF1 cytoplasm in sunflower hybrid breeding

The use of the new cytoplasmic male sterility (CMS) source PEF1 in sunflower hybrid breeding requires markers closely linked to the restorer gene Rf_PEF1 necessary for fertility restoration of hybrids based on the PEF1 cytoplasm as well as diagnostic markers to distinguish the PEF1 cytoplasm from other cytoplasms. Bulked segregant analyses of 256 AFLP primer combinations identified 35 polymorphic primer combinations with 1–3 polymorphisms, resulting in 40 polymorphisms. Eighteen AFLP markers mapped together with the Rf_PEF1 gene covering 119.9 cM. The closest markers, E39M51_300R and E44M56_112A, mapped 3.9 and 6.0 cM to the Rf_PEF1 gene, respectively. Six SSR markers, which belong to the linkage group 13, were screened for polymorphisms between the parental lines. Only ORS630 was polymorphic, but did not map to the same linkage group as Rf_PEF1, indicating that Rf_PEF1 is not located on linkage group 13 where the restorer gene Rf1 for the PET1 cytoplasm is located. Diagnostic markers to distinguish the PEF1 cytoplasm from the PET1 and the fertile cytoplasm in sunflower were obtained using primer combinations for the atp9 gene and orfH522.     

Comparative genetic analysis and molecular mapping of fertility restoration genes for WA,Dissi, and Gambiaca cytoplasmic male sterility systems in rice

The genetic relationship among three cytoplasmic male sterility (CMS) systems, consisting of WA, Dissi, and Gambiaca, was studied. The results showed that the maintainers of one CMS system can also maintain sterility in other cytoplasmic backgrounds. The F₁ plants derived from crosses involving A and R lines of the respective cytoplasm and their cross-combination with other CMS systems showed similar pollen and spikelet fertility values, indicating that similar biological processes govern fertility restoration in these three CMS systems. The results from an inheritance study showed that the pollen fertility restoration in all three CMS systems was governed by two independent and dominant genes with classical duplicate gene action. Three F₂ populations, generated from the crosses between the parents of good-performing rice hybrids, that possess WA, Dissi, and Gambiaca CMS cytoplasm, were used to map the Rf genes. For the WA-CMS system, Rf3 was located at a distance of 2.8 cM from RM490 on chromosome 1 and Rf4 was located at 1.6 cM from RM1108 on chromosome 10. For the Dissi-CMS system, Rf3 was located on chromosome 1 at 1.9 cM from RM7466 and Rf4 on chromosome 10 was located at 2.3 cM from RM6100. The effect of Rf3 on pollen fertility appeared to be stronger than the effect of Rf4. In the Gambiaca-CMS system, only one major locus was mapped on chromosome 1 at 2.1 cM from RM576. These studies have led to the development of marker-assisted selection (MAS) for selecting putative restorer lines, new approaches to alloplasmic line breeding, and the transfer of Rf genes into adapted cultivars through a backcrossing program in an active hybrid rice breeding program.     

Identification of the Rf gene conferring fertility restoration of the CMS Dian-type 1 in rice by using simple sequence repeat markers and advanced inbred lines of restorer and maintainer

Cytoplasmic male sterility of Dian‐type 1 (CMS‐D1) was developed 30 years ago in Yunnan. A major gene conferring fertility restoration for the CMS‐D1 system was detected by microsatellite markers in advanced inbred lines consisting of 196 maintainers and 62 restorers developed in breeding programmes of hybrid rice involving the CMS‐D1 system. The gene was mapped between two simple sequence repeat markers, OSR33 and RM228, on chromosome 10, and was temporarily designated as Rf‐D1(t). The genetic distances of the gene to the two microsatellite markers were 3.4 and 5.0 cM, respectively. This linkage was confirmed by using an F2 population derived from a cross between a CMS‐D1 line and a restorer. This study also demonstrated that using OSR33 was reliable and efficient for identification of restoring lines in hybrid rice breeding with the CMS‐D1 system.     

Fine mapping of Rf2, a major locus controlling pollen fertility restoration in sorghum A1 cytoplasm,encodes a PPR gene and its validation through expression analysis

Sorghum is one of the pioneering cereal crops where cytoplasmic male sterility (CMS) was successfully exploited for mass production of F₁ hybrid seed. Mapping genes for fertility restoration (Rf) is an important aspect of understanding the molecular basis of fertility restoration in crop plants. In this study, we fine‐mapped a fertility restoration locus, Rf2 of sorghum reported earlier (Jordan, Mace, Henzell, Klein, & Klein, 2010 ), involving two F₂ populations (296A × RS29 and 296A × DSV1) and newly developed SSR markers delimited Rf2 locus to 10.32‐kb region on chromosome 2. The Rf2 locus was tightly linked with two new SSRs, MS‐SB02‐3460 (0.14 cM) and MS‐SB02‐3466 (0.75 cM) on both sides, and hosted only one gene (Sobic.002G057050) of PPR gene family. Another new SSR marker developed in the study, MS‐SB02‐37912, forms the part of PPR gene and could act as a perfect marker in marker‐assisted breeding for fertility restoration involving Rf2 in sorghum breeding. The strong involvement of Sobic.002G057050 gene in fertility restoration was supported through RNA expression analysis.     

Molecular mapping of a fertility restorer gene for cytoplasmic male sterility in soybean

In this study, we report the mapping of the Rf locus in soybean by microsatellite simple sequence repeat (SSR) genetic markers. A cross was made between cytoplasmic male sterility (CMS) line JLCMS82A and restorer line JIHUI 1 based on the DNA polymorphisms revealed by 109 SSR markers. A F₂ population derived from a single F₁ plant containing 103 individuals was used for mapping the Rf locus. The Rf gene of JIHUI 1 gametophytically restores male fertility to JLCMS82A. Fertile and semi-fertile DNA bulks and parental DNAs were screened with 219 SSR markers, and Satt215 which was previously mapped to soybean LG J, was found linked to the Rf gene. Five additional polymorphic SSR markers from LG J were used for analysis and a regional linkage map around the Rf locus was established. SSR markers, Sctt011 and Satt547, flanked the Rf locus at 3.6 cM and 5.4 cM, respectively. The availability of these SSR markers will facilitate the selection of restorer lines in hybrid soybean breeding.     

Tagging of four fertility restorer loci for wild abortive—cytoplasmic male sterility system in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) using microsatellite markers

Tagging of restorer genes for wild abortive (WA) CMS source by studying a 222 individual plants from a F₂ population of a cross between IR58025A × IR42686R. The restorer line IR42686R that was used in this study had been previously derived through random mating composite population (RMCP) involving 12 parents facilitated by IR36 genetic male sterility. Four Rf genes were tagged to simple sequence repeats (SSR) markers on chromosomes 1, 7, 10, 12 by recessive class analysis. The recombination frequency between a positive marker and Rf locus was calculated using maximum likelihood estimator assuming that all the 46 extremely sterile individual plants were homozygous at the targeted Rf locus. The recombination frequency between the marker and the restorer trait were converted to genetic distances using Kosambi function. A new Rf locus designated as Rf7 on chromosome 12 was found to be linked to RM7003 at a genetic distance of 13.3 cM (LOD 6.12). We report here first, a new molecular marker (RM 6344) linked to Rf4 locus on chromosome 7 that was previously mapped by trisomic analysis. RM443 and RM315 were flanking the Rf3 gene at a genetic distance of 4.4 (LOD 10.29) and 20.7 cM (LOD 3.98) on chromosome 1, respectively. The Rf6 was flanked on both side with SSR markers RM258 and RM591 at a genetic distance of 4.4 (LOD 10.29) and 23.3 cM (LOD 3.39) located on chromosome 10. The random mating composite population is an excellent breeding approach to develop superior restorer lines and for pyramiding different Rf genes of different CMS systems. Rf genes tagged with closely linked SSR markers would be facilitating marker assisted selection (MAS) in hybrid rice breeding program by reducing time and workload for identifying potential restorers. L. Bazrkar and A. J. Ali equally contributed to this work.     

Genetic mapping for the Rf1 (fertility restoration) gene in sunflower (Helianthus annuus L.) by SSR and TRAP markers

The Rf1 gene in sunflower can effectively restore the pollen fertility of PET1 cytoplasm in male-sterile lines and has been widely used in commercial hybrid production. Identifying molecular markers tightly linked to this gene will be useful in marker-assisted selection to develop maintainer and restorer lines. Rf1 has been mapped to Linkage Group (LG) 13 of the public sunflower simple sequence repeat (SSR) map by aligning maps constructed from different populations and only one SSR marker was reported to be loosely linked to Rf1 . This paper reports the result of applying target region amplification polymorphism (TRAP) and SSR markers to map and develop a sequence-tagged site (STS) marker tightly linked to Rf1 using two populations derived from a cross between two U.S. public sunflower lines, RHA439 and cmsHA441. An SSR marker, ORS511, was 3.7 cM from the Rf1 gene and a TRAP marker, K11F05Sa12-160, was linked to Rf1 at a distance of 0.4 cM. This TRAP marker was converted to an STS marker for using in sunflower breeding.     

A simple method to control the seed purity of japonica hybrid rice varieties using PCR-based markers

Cytoplasmic male sterility (CMS) by the cms‐bo cytoplasm and its restoration by the nuclear restorer gene, Rf‐1, are used for seed production of japonica hybrid rice varieties. To produce pure hybrid seeds, a prerequisite is to properly manage the seed purity of parental lines, especially CMS lines. In this study, three dominant polymerase chain reaction (PCR)‐based markers (M1, M2 and M3) were developed to detect mutual contamination in seed batches of CMS lines, maintainer lines, restorer lines and hybrids. M1 detected the mitochondrial sequence that was present in the cytoplasm of common japonica varieties and absent in the cms‐bo cytoplasm. M2 and M3 detected the chromosomal sequence related to the Rf‐1 allele in restorer lines and the rf‐1 allele in common japonica varieties, respectively. By the strategic use of these markers, japonica hybrids and their parental lines could be efficiently distinguished from each other. Furthermore, sensitivity tests for the three markers with a series of crude DNA samples prepared from polished grains demonstrated that these markers could detect one contaminating grain among 500 or 1000 grains. Therefore, the bulk PCR analyses with the markers developed here probably make it possible to control the seed purity of japonica hybrids properly by selecting appropriate seed batches of their parental lines quickly and efficiently.     

雄性不育系“NEWFREE”的特点及其在观赏向日葵中的利用

雄性不育（male sterility）是向日葵杂种优势利用的重要途径。目前，全世界均是利用细胞质雄性不育性生产商用杂交种，因此，向日葵雄性不育性的发现和利用是育种学家们研究的重要课题。本研究采用了不同地理来源的20份自交系材料作育性试验，结果表明, “NEWFREE”雄性不育系具有与PET1完全不同的恢复系和保持系，很可能是     

Molecular mapping of the fertility-restoration gene Rf4 for WA-cytoplasmic male sterility in rice

The wild abortive cytoplasmic male sterility (CMS‐WA) system, an ideal type of sporophytic CMS in indica rice, is used for the large‐scale commercial production of hybrid rice. Searching for restorer genes is a good approach when phenotyping is very time‐consuming and requires the determination of spikelet sterility in testcross progeny. To establish more precisely the genetical and physical maps of the Rf4 gene, high‐resolution mapping of this locus was carried out using simple sequence repeat (SSR) markers and newly designed markers in a F₂ population. The genetic linkage analysis indicated that five SSR markers (RM6737, RM304, RM171, RM5841 and RM228) on the long arm of chromosome 10 were linked with the Rf4 gene. Rf4 was flanked by two SSR markers RM171 and RM6737 at distances of 3.2 and 1.6 cM, respectively. Also, within the region between Rf4 gene and RM171, a newly designed primer pair, AB443, produced two sterile‐specific markers, AB443‐400 and AB443‐500, 0.5 and 1.03 cM from the gene. The flanking markers identified give promise for their application in molecular marker‐assisted selection (MAS) and they are also suitable for starting chromosome walking to clone Rf4 gene in the near future.     

与高粱A2类型细胞质雄性不育性连锁的SSR标记的初步鉴定

高粱(Sorghum bicolor(L.)Moench)质核互作雄性不育类型有7种,即A1,A2,A3,A4,A5,A6和9E.对于雄性不育机理的研究以往都集中在A1类型上.本文运用SSR方法分析了高粱亲本622 A2,晋粱5号,它们的杂交种622 A2×晋粱5号,及其F2代323个单株的DNA,从60对SSR引物中筛选到与不育基因连锁的SSR标记Xtxp 65和Xtxp30,分别位于目的基因11.5 cM和20.0 cM处,其特异带型大小分别约为125 bp和250 bp.分子标记的有效利用有利于优良高粱不育系的选择,也为基于作图的基因分离奠定了基础.     

Molecular mapping of a dominant genic male sterility gene Ms in rapeseed (Brassica napus)

Rs1046AB is a genic male sterile two‐type line in rapeseed that has great potential for hybrid seed production. The sterility of this line is conditioned by the interaction of two genes, i.e. the dominant genic male sterility gene (Ms) and the suppressor gene (Rf). The present study was undertaken to identify DNA markers for the Ms locus in a BC₁ population developed from a cross between a male‐sterile plant in Rs1046AB and the fertile canola‐type cultivar ‘Samourai’. Bulked segregant analysis was performed using the amplified fragment length polymorphism (AFLP) methodology. From the survey of 480 AFLP primer combinations, five AFLP markers (P10M13₃₅₀, P13M8₄₀₀, P6M6₄₁₀, E7M1₂₃₀ and E3M15₁₀₀) tightly linked to the target gene were identified. Two of them, E3M15₁₀₀ and P6M6₄₁₀, located the closest, at either side of Ms at a distance of 3.7 and 5.9 cM, respectively. The Ms locus was subsequently mapped on linkage group LG10 in the map developed in this laboratory, adding two additional markers weakly linked to it. This suite of markers will be valuable in designing a marker‐assisted genic male sterility three‐line breeding programme.     

The restorer gene for soybean M‐type cytoplasmic male sterility,Rf‐m,is located in a PPR gene‐rich region on chromosome 16

Over the past decade, M‐type cytoplasmic male sterility (CMS) line W931A and a variety of restorer lines have been exploited for the release of hybrid seeds in soybean (Glycine max). However, the identities of restorer genes in the nuclei of soybean restorer lines are still unclear. In this study, we analysed the inheritance pattern of restorer locus Rf‐m from restorer line WR016 and constructed a high‐resolution map of this locus. Results showed that Rf‐m in WR016 is a monogenic dominant gene located within a 162.4‐kb region on chromosome 16, which is flanked on each side by new developed simple sequence repeat (SSR) markers GmSSR1602 and GmSSR1610 at a distance of 0.11 and 0.25 cM, respectively. Nineteen open reading frames (ORFs) were predicted in this region. Of these, seven genes arranged in tandem on chromosome 16 encode pentatricopeptide repeat (PPR) proteins, which is similar to other reported restorer loci in plants. These results lay a solid foundation for map‐based cloning of the Rf‐m gene and will be helpful for marker‐assisted selection of elite CMS restorer lines.     

Fine mapping of <Emphasis Type="Italic">Rf3</Emphasis> and <Emphasis Type="Italic">Rf4</Emphasis> fertility restorer loci of WA-CMS of rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) and validation of the developed marker system for identification of restorer lines

The Wild Abortive (WA) system is the major cytoplasmic male sterility (CMS) source for hybrid rice production in indica rice and its fertility restoration is reported to be controlled by two major loci viz. Rf3 on chromosome 1 and Rf4 on chromosome 10. With the availability of the rice genome sequence, an attempt was made to fine map, develop candidate gene based markers for Rf3 and Rf4 and validate the developed marker system in a set of known restorer lines. Using polymorphic markers developed from microsatellite markers and candidate gene based markers from Rf3 and Rf4 loci, local linkage maps were constructed in two mapping populations of ~1,500 F₂ progeny from KRH2 (IR58025A/KMR3R) and DRRH2 (IR68897A/DR714-1-2R) hybrids. QTLs and their interactions for fertility restoration in Rf3 and Rf4 loci were identified. The identified QTL in both mapping populations together explained 66–72 % of the phenotypic variance of the trait suggesting their utility in developing a marker system for identification of fertility restorers for WA-CMS. Sequence comparison of the two candidate genes from the Rf3 and Rf4 regions in male sterile (A) and restorer (R) lines showed 2–3 bp indels and a few substitutions in the Rf3 region and indels of 327 and 106 bp in the Rf4 region respectively. The marker system identified in the present study was validated in 212 restorers and 34 maintainers along with earlier reported markers for fertility restoration of WA-CMS. Together DRCG-RF4-14 and DRCG-RF4-8 for the Rf4 locus and DRRM-RF3-5/DRRM-RF3-10 for the Rf3 locus showed a maximum efficiency of 92 % for identification of restorers.     

Development and use of a two-gene marker-aided selection system for fertility restorer genes in rice

We have established marker-aided selection strategies for the two major Rf genes (Rf3 and Rf4) governing fertility restoration of␣cytoplasmic-genetic male sterility (CMS) in rice. Polymorphisms between restorer and non-restorer␣lines were observed using RG140/PvuII for Rf3 located on chromosome 1 and S10019/BstUI for Rf4 located on chromosome 10. DNA polymorphisms associated with these two loci in restorer lines of wild abortive (WA), Dissi, and Gambiaca cytoplasm are conserved, suggesting that similar biological processes control pollen fertility in this diverse cytoplasm. Because of their close linkage to Rf genes and distinct banding patterns, STS markers RG140/PvuII and S10019/BstUI are well suited for marker-aided selection, enhanced backcross procedures, and pyramiding of Rf genes in agronomically superior non-restorer lines. The combined use of markers associated with these two loci improved the efficiency of screening for putative restorer lines from a set of elite lines. Positional analyses of Rf4 and the inheritance pattern of the polymorphism in S10019/BstUI suggest that Rf4, governing fertility restoration in WA-CMS in rice, is likely to be the same gene governing fertility restoration in BT- and HL-CMS that has a gametophytic effect, which explains why 100% pollen fertility in hybrids is impossible to attain.     

Identification of AFLP markers linked to the epistatic suppressor gene of a recessive genic male sterility in rapeseed and conversion to SCAR markers

A recessive epistatic genic male sterility (REGMS) two‐type line, 9012AB, has been used for rapeseed hybrid seed production in China. The male sterility of 9012AB is controlled by two recessive duplicate sterile genes (ms1 and ms2) interacting with one recessive epistatic suppressor gene (esp). Homozygosity at the esp locus (espesp) suppresses the expression of the recessive male sterility trait in homozygous ms1ms1ms2 ms2 plants. In this study, we used a combination of bulked segregant analyses and amplified fragment length polymorphism (AFLP) to identify markers linked to the suppressor gene in a BC₁ population. From the survey of 1024 AFLP primer combinations, eight markers tightly linked to the target gene were identified. The two closest markers flanking both sides of Esp, P9M5₃₇₀ and S16M14₇₈₀, had a genetic distance of 1.4 cM and 2.1 cM, respectively. The AFLP fragment from P4M8₁₉₀, which co‐segregated with the target gene was converted into a sequence characterized amplified region marker. The availability of linked molecular markers will facilitate the utilization of REGMS in hybrid breeding in Brassica napus.     

Inheritance and allelic relationships of fertility restoration genes for seven new sources of male-sterile cytoplasm in sunflower

The inheritance of fertility restoration of six mitomycin C and streptomycin‐induced cytoplasmic male‐sterile (cms) mutants and one cms line derived from Native American cultivar PI 432513 in sunflower was evaluated. These seven new cms sources were also compared with the commercially used cms PET1 (Helianthus petiolaris Nutt.) cytoplasm, using USDA inbred lines with restoration genes (Rf₁) specific for cms PET1 and new restoration lines identified for cms PI 432513. Restoration genes for cms PI 432513 were found in ‘Armavir’, VNIIMK, P21 and male‐fertile (MF) plants of PI 432513. F₂ and F₃ segregation ratios of crosses between cms PI 432513 and these restoration sources indicated a single dominant gene controlled fertility restoration. Progenies of cms PI 432513 testcrossed with F₁’s of half‐diallel crosses among the respective four homozygous restoration lines and RHA 274 suggested that the restoration genes of RHA 274, VNIIMK, P21 and PI 432513 were at the same locus. Restoration genes from VNIIMK, P21 and PI 432513 satisfactorily restored pollen stainability in the heterozygous condition. A very weak expression of the Rf gene in ‘Armavir’ was observed in the heterozygous condition. Fertility restoration capability of these genes for the six mutant cms HA 89 and cms HA 89 (in PET1 cytoplasm) was observed. The mutant cms HA 89 lines were also restored completely by RHA 266, RHA 274, RHA 280 and RHA 296, and F₂’s segregation ratios indicated single dominant gene control, implying a common cytoplasmic male sterility in all lines. F₁’s of half‐diallel crosses among RHA 266, RHA 273, RHA 274, RHA 280 and RHA 296 were testcrossed onto the cms lines, and their all MF progenies among lines, except RHA 280, confirmed that fertility restoration was controlled by a single Rf₁ gene locus. The restoration gene in confection line RHA 280, namely Rf₃, was at a different locus than Rf₁ and was equally capable of restoring all the cms lines. Cms HA 89 mutants and cms PI 432513 are in H. annuus cytoplasm, and are agronomically equal in hybrid performance to the cms PET1 used in commercial sunflower hybrids. These new cms lines will provide immediate alternative cms sources for reducing the genetic vulnerability resulting from the exclusive use of the single cms source PET1 in sunflower hybrid production.     

Interspecific amphiploid‐derived alloplasmic male sterility with defective anthers,narrow disc florets and small ray flowers in sunflower

The cytoplasmic male‐sterility (CMS)/fertility‐restoration system is important for hybrid sunflower (Helianthus annuus L.) seed production. The objective of this study was to characterize two novel alloplasmic CMSs, designated CMS GRO1 and CMS MAX3, with defective anthers, narrow disc florets with no swollen corolla, and short, narrow ray flowers derived from two tetraploid amphiploids (AMPs). Among 26 tested lines, only AMP Helianthus cusickii/P 21 and HA 410 failed to restore male‐fertility. Segregation of CMS, male‐fertile plants and plants with reduced male‐fertility was observed both in the testcross progeny of a six line half‐diallel cross of F₁s with CMS MAX3 and in an F₂ population of CMS GRO1 × RHA 274. Male‐fertility restoration was controlled by at least two dominant genes. Detailed analysis of the mitochondrial genes may provide insight into the differences between these CMSs and other CMS lines. The new CMSs will facilitate the studies of the incompatibility between cytoplasmic and nuclear genes, especially for the alloplasmic CMS involving perennial species, and also provide unique ornamental flower types and CMS sources for hybrid sunflower breeding.     

Molecular mapping of S-c, an F1 pollen sterility gene in cultivated rice

Hybrids between indica and japonica rice varieties usually show partial sterility, and are a major limiting factor in the utilization of heterosis at subspecific level. When studying male-gamete (pollen) abortion, a possibly important cause for sterility, six loci (S-a, S-b, S-c, S-d, S-e and S-f) for F₁ pollen sterility were identified. Here we report genetic and linkage analysis of S-c locus using molecular markers in a cross between Taichung 65, a japonica variety carrying allele S-c ^j, and its isogenic line TISL5, carrying alleleS-c ^j. Our results show that pollen sterility occurring in the hybrids is controlled by one locus. We used 208 RFLP markers, as well as 500 RAPD primers, to survey the polymorphism between Taichung 65 and TISL5. Six RFLP markers located on a small region of chromosome 3, detected different RFLP patterns. Co-segregation analysis of fertility and RFLP patterns with 123 F₂ plants confirmed that the markers RG227, RG391, R1420 were completely linked with the S-c locus. The genetic distances between the markers C730, RG166 and RG369 and the S-c locus were 0.5 cM, 3.4 cM, and 3.4 cM respectively. Distorted F₂ ratios were also observed for these 4 RFLP markers in the cross. This result suggests that the `one locus sporo-gametophytic' model could explain F₁ hybrid pollen sterility in cultivated rice. RG227, the completely linked marker, has been converted to STS marker for marker-assisted selection. This revised version was published online in August 2006 with corrections to the Cover Date.     

Morphological and cytological study in a new type of cytoplasmic male-sterile line CMS-GIG2 in sunflower (Helianthus annuus)

Cytoplasmic male sterility (CMS) is essential for sunflower hybrid production. CMS-GIG2, a new sunflower CMS type, was further confirmed by crossing with the maintainer and restorer lines for the CMS-PET1, both of which maintain the male sterility of CMS-GIG2. Meiotic division in CMS-GIG2 was observed with 4'6-diamidino-2-phenylindole dihydrochloride staining, indicating that microspore formation was disrupted before the meiotic cytokinesis was completed. Light microscopy observation showed that both middle layer and tapetal cells expand radially rather than degrade over time, followed by failure to form tetrads and normal microspores. This morphological defect leading to male sterility in CMS-GIG2 differs from that observed in the PET1 CMS type. CMS-GIG2 will certainly provide additional genetic diversity for sunflower hybrid breeding programmes.